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Email : zainab_talib2009@yahoo

Lec 8. Hydraulics of Open Channel Flow. Dr. Zainab Talib Al-Sharify. Email : zainab_talib2009@yahoo.com. Summary. Lecture 8-9 Varied flow (Non uniform flow) Maximum discharge and max velocity in circular pipe. Type of gradually varied flow

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Email : zainab_talib2009@yahoo

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  1. Lec 8 Hydraulics of Open Channel Flow Dr. Zainab Talib Al-Sharify Email: zainab_talib2009@yahoo.com

  2. Summary • Lecture 8-9 • Varied flow (Non uniform flow) • Maximum discharge and max velocity in circular pipe. • Type of gradually varied flow • Calculation of gradually varied flow- direct step method • Extended or Distorted Channel • Tutorial questions (selected question) • Home work (Q 10.51to 10.100) • Lecture 10-15 • Specific force hydraulic jump. • Application of Hydraulic jump. • Measurement of flow in open channels • Venture meters, Nozzles orifices

  3. Hydraulic jump A hydraulic jump is a phenomenon in the science of hydraulics which is frequently observed in open channel flow such as rivers and spillways. When liquid at high velocity discharges into a zone of lower velocity, a rather abrupt rise occurs in the liquid surface. Hydraulic jumps can be seen in both a stationary form, which is known as a "hydraulic jump", and a dynamic or moving form, which is known as a positive surge or "hydraulic jump in translation".[16] They can be described using the same analytic approaches and are simply variants of a single phenomenon.[15][16][18]

  4. hydraulic jump

  5. Specific force hydraulic jump.

  6. https://www.youtube.com/watch?v=tGX5gIgqeYY

  7. Stationary hydraulic jump[edit] A stationary hydraulic jump is the type most frequently seen on rivers and on engineered features such as outfalls of dams and irrigation works. They occur when a flow of liquid at high velocity discharges into a zone of the river or engineered structure which can only sustain a lower velocity. When this occurs, the water slows in a rather abrupt rise (a step or standing wave) on the liquid surface.[17] Comparing the characteristics before and after, one finds:

  8. Descriptive Hydraulic Jump Characteristics The other stationary hydraulic jump occurs when a rapid flow encounters a submerged object which throws the water upwards. The mathematics behind this form is more complex and will need to take into account the shape of the object and the flow characteristics of the fluid around it.

  9. Analysis of the hydraulic jump on a liquid surface In spite of the apparent complexity of the flow transition, application of simple analytic tools to a two dimensional analysis is effective in providing analytic results which closely parallel both field and laboratory results. Analysis shows: Height of the jump: the relationship between the depths before and after the jump as a function of flow rate[18] Energy loss in the jump Location of the jump on a natural or an engineered structure Character of the jump: undularor abrupt

  10. Energy dissipation by a hydraulic jump One of the most important engineering applications of the hydraulic jump is to dissipate energy in channels, dam spillways, and similar structures so that the excess kinetic energy does not damage these structures. The rate of energy dissipation or head loss across a hydraulic jump is a function of the hydraulic jump inflow Froude number and the height of the jump.[15] The mathematical formula for Energy loss in hydraulic jump is as follows: where: y1 - upstream flow depth; y2 - downstream flow depth

  11. Location of hydraulic jump in a streambed or an engineered structure In the design of a dam the energy of the fast-flowing stream over a spillway must be partially dissipated to prevent erosion of the streambed downstream of the spillway, which could ultimately lead to failure of the dam. This can be done by arranging for the formation of a hydraulic jump to dissipate energy. To limit damage, this hydraulic jump normally occurs on an apron engineered to withstand hydraulic forces and to prevent local cavitation and other phenomena which accelerate erosion.

  12. In the design of a spillway and apron, the engineers select the point at which a hydraulic jump will occur. Obstructions or slope changes are routinely designed into the apron to force a jump at a specific location. Obstructions are unnecessary, as the slope change alone is normally sufficient. To trigger the hydraulic jump without obstacles, an apron is designed such that the flat slope of the apron retards the rapidly flowing water from the spillway. If the apron slope is insufficient to maintain the original high velocity, a jump will occur.

  13. Two methods of designing an induced jump are common: • If the downstream flow is restricted by the down-stream channel such that water backs up onto the foot of the spillway, that downstream water level can be used to identify the location of the jump. • If the spillway continues to drop for some distance, but the slope changes such that it will no longer support supercritical flow, the depth in the lower subcritical flow region is sufficient to determine the location of the jump.

  14. In both cases, the final depth of the water is determined by the downstream characteristics. The jump will occur if and only if the level of inflowing (supercritical) water level ( ) satisfies the condition:

  15. Industrial and recreational applications for hydraulic jumps Industrial The hydraulic jump is the most commonly used choice of design engineers for energy dissipation below spillways and outlets. A properly designed hydraulic jump can provide for 60-70% energy dissipation of the energy in the basin itself, limiting the damage to structures and the streambed. Even with such efficient energy dissipation, stilling basins must be carefully designed to avoid serious damage due to uplift, vibration, cavitation, and abrasion. An extensive literature has been developed for this type of engineering

  16. Recreational While travelling down river, kayaking and canoeing paddlers will often stop and playboat in standing waves and hydraulic jumps. The standing waves and shock fronts of hydraulic jumps make for popular locations for such recreation. for such recreation. Similarly, kayakers and surfers have been known to ride tidal bores up rivers. Hydraulic jumps have been used by glider pilots in the Andes and Alps[27] and to ride Morning Glory effects in Australia.

  17. Measurement of flow in open channels some of the more common methods currently in use to measure open channel flows are:  Timed Gravimetric Tracer-Dilution Area-Velocity Manning’s Equation / (Gauckler-Manning-Strickler Formula) Hydraulic Structures (Flumes & Weirs) https://www.openchannelflow.com/blog/methods-of-measuring-flows-in-open-channels

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